Control of heme synthesis during Friend cell differentiation: role of iron and transferrin

In many types of cells the synthesis of delta-aminolevulinic acid (ALA) limits the rate of heme formation. However, results from our laboratory with reticulocytes suggest that the rate of iron uptake from transferrin (Tf), rather than ALA synthase activity, limits the rate of heme synthesis in erythroid cells. To determine whether changes occur in iron metabolism and the control of heme synthesis during erythroid cell development Friend erythroleukemia cells induced to erythroid differentiation by dimethylsulfoxide (DMSO) were studied. While added ALA stimulated heme synthesis in uninduced Friend cells (suggesting ALA synthase is limiting) it did not do so in induced cells. Therefore the possibility was investigated that, in induced cells, iron uptake from Tf limits and controls heme synthesis. Several aspects of iron metabolism were investigated using the synthetic iron chelator salicylaldehyde isonicotinoyl hydrazone (SIH). Both induced and uninduced Friend cells take up and utilize Fe for heme synthesis directly from Fe-SIH without the involvement of transferrin and transferrin receptors and to a much greater extent than from saturating levels of Fe-Tf (20 microM). Furthermore, in induced Friend cells 100 microM Fe-SIH stimulated 2-14C-glycine incorporation into heme up to 3.6-fold as compared to the incorporation observed with saturating concentrations of Fe-Tf. In contrast, Fe-SIH, even when added in high concentrations, did not stimulate heme synthesis in uninduced Friend cells but was able to do so as early as 24 to 48 h following induction. In addition, contrary to previous results with rabbit reticulocytes, Fe-SIH also stimulated globin synthesis in induced Friend cells above the level seen with saturating concentrations of transferrin. These results indicate that some step(s) in the pathway of iron from extracellular Tf to protoporphyrin, rather than the activity of ALA synthase, limits and controls the overall rate of heme and possibly hemoglobin synthesis in differentiating Friend erythroleukemia cells.     

Inhibition of heme synthesis decreases transferrin receptor expression in mouse erythroleukemia cells.

The coordination of transferrin receptor (TfR) expression and heme synthesis was investigated in mouse erythroleukemia (MEL) cells of line 707 treated with heme synthesis inhibitors or in a variant line Fw genetically deficient in heme synthesis. Cells of line 707 were induced for differentiation by 5 mM hexamethylene bisacetamide (HMBA). TfR expression increased in the course of induction, as judged by increased TfR mRNA synthesis, increased cytoplasmic TfR mRNA level, and by the increased number of cellular 125I-Tf binding sites. Addition of 0.1 mM succinylacetone (SA) decreased cellular TfR to the level comparable with the uninduced cells. The decrease was reverted by the iron chelator desferrioxamine (DFO) but not by exogenous hemin. In short-term (1-2 hours) incubation, SA inhibited 59Fe incorporation from transferrin into heme, whereas total cellular 59Fe uptake was increased. A decrease in TfR mRNA synthesis was apparent after 2 hours of SA treatment. Conversely, glutathione peroxidase mRNA synthesis, previously shown to be inducible by iron, was increased by SA treatment. Cells of heme deficient line Fw did not increase the number of Tf binding sites after the induction of differentiation by 5 mM sodium butyrate. SA had no effect on TfR expression in Fw cells. The results suggest that the depletion of cellular non-heme iron due to the increase in heme synthesis maintains a high level of transferrin receptor expression in differentiating erythroid cells even after the cessation of cell division.     

Biphasic ordered induction of heme synthesis in differentiating murine erythroleukemia cells: role of erythroid 5-aminolevulinate synthase.

During dimethyl sulfoxide (DMSO)-stimulated differentiation of murine erythroleukemia (MEL) cells, one of the early events is the induction of the heme biosynthetic pathway. While recent reports have clearly demonstrated that GATA-1 is involved in the induction of erythroid cell-specific forms of 5-aminolevulinate synthase (ALAS-2) and porphobilinogen (PBG) deaminase and that cellular iron status plays a regulatory role for ALAS-2, little is known about regulation of the remainder of the pathway. In the current study, we have made use of a stable MEL cell mutant (MEAN-1) in which ALAS-2 enzyme activity is not induced by DMSO, hexamethylene bisacetamide (HMBA), or butyric acid. In this cell line, addition of 2% DMSO to growing cultures results in the normal induction of PBG deaminase and coproporphyrinogen oxidase but not in the induction of the terminal two enzymes, protoporphyrinogen oxidase and ferrochelatase. These DMSO-treated cells did not produce mRNA for beta-globin and do not terminally differentiate. In addition, the cellular level of ALAS activity declines rapidly after addition of DMSO, indicating that ALAS-1 must turn over rapidly at this time. Addition of 75 microM hemin alone to the cultures did not induce cells to terminally differentiate or induce any of the pathway enzymes. However, the simultaneous addition of 2% DMSO and 75 microM hemin caused the cells to carry out a normal program of terminal erythroid differentiation, including the induction of ferrochelatase and beta-globin. These data suggest that induction of the entire heme biosynthetic pathway is biphasic in nature and that induction of the terminal enzymes may be mediated by the end product of the pathway, heme. We have introduced mouse ALAS-2 cDNA into the ALAS-2 mutant cell line (MEAN-1) under the control of the mouse metallothionein promoter (MEAN-RA). When Cd and Zn are added to cultures of MEAN-RA in the absence of DMSO, ALAS-2 is induced but erythroid differentiation does not occur and cells continue to grow normally. In the presence of metallothionein inducers and DMSO, the MEAN-RA cells induce in a fashion similar to that found with the wild-type 270 MEL cells. Induction of the activities of ALAS, PBG deaminase, coproporphyrinogen oxidase, and ferrochelatase occurs. In cultures of MEAN-RA where ALAS-2 had been induced with Cd plus Zn 24 h prior to DMSO addition, onset of heme synthesis occurs more rapidly than when DMSO and Cd plus Zn are added simultaneously. This study reveals that induction of ALAS-2 alone is not sufficient to induce terminal differentiation of the MEAN-RA cells, and it does not appear that ALAS-2 alone is the rate-limiting enzyme of the heme biosynthetic pathway during MEL cell differentiation.     

Relationship of Friend murine leukemia virus production to growth and hemoglobin synthesis in cultured erythroleukemia cells.

The factors that control oncornavirus formation were analyzed in Friend leukemia cells that undergo hematopoiesis when treated with dimethyl sulfoxide. Suspension cultures of Ostertag FSD-1 cell line were found to enter a G or resting state at the end of their proliferative phase and to simultaneously cease producing helper and dependent components of Friend virus. Whereas the decline in virus production is at least 100-fold, rates of cellular RNA and protein synthesis are only slightly lower in resting than in growing cells. Both resting and growing cells contain similarly large concentrations of the viral proteins P(30) and P(12). Dimethyl sulfoxide induces hemoglobin synthesis in growing cells, but its effects on virus production appear to be indirect results of its action to inhibit cell growth and thus to delay entry of cells into the G resting state. Furthermore, variant cell lines were obtained with differing abilities to synthesize virus or hemoglobin. Some lines no longer produce infectious virus, although they all harbor murine leukemia virus genes which are expressed to varying extents. The major internal protein of these oncornaviruses, P(30), is synthesized in large amounts by all of the cell lines. These results suggest that Friend virus production is not coinduced with erythroid differentiation, as had been proposed, but rather is controlled by a cellular growth cycle.     

Distribution of interdivisional times in proliferating and differentiating Friend murine erythroleukaemia cells

The interdivisional times of Friend murine erythroleukaemia cells which are growing continuously, or during terminal erythroid differentiation after exposure to dimethyl sulphoxide (DMSO), were determined by time lapse video photography. The median interdivisional times were found to increase from 11.75 hr before exposure to DMSO, to 24.0 hr at 72 hr after exposure. This increase in median interdivisional time was accompanied by an increase in heterogeneity of interdivisional times (%CV = 8.5----40.8), by an increase in the similarity of sister interdivisional times (ryy = 0.622----0.925), and by a decrease in the fraction of cells observed to divide (F = 1.0----0.807). Cells exposed to DMSO for 72 hr can be induced to divide at least once with nearly normal interdivisional times, if they are resuspended at a tenfold higher cell concentration. Computer simulations of cell cycle regulation, based on the opposing reactions model of Murphy, generate interdivisional time distributions which resemble the experimental data better than the single transition probability model of Smith and Martin.     

Deficient heme synthesis as the cause of noninducibility of hemoglobin synthesis in a Friend erythroleukemia cell line.

Friend cells of the line Fw are not induced to accumulate substantial amounts of hemoglobin and to become benzidine-positive when treated with butyric acid or other inducers, except in the presence of exogenous hemin. The cells are shown to have a deficiency in heme synthesis since they require exogenous hemin during the period of maximal hemoglobin synthesis; since endogenous heme synthesis cannot be induced to the level found in normal inducible Friend cells, even after hemoglobin synthesis has been induced by hemin and butyric acid and the hemin has then been withdrawn; since they are not inducible for ferrochelatase (heme synthetase) activity; and since they accumulate free globin chains after stimulation with butyric acid in the absence of hemlin. Comparison of globin synthesis and globin mRNA content of the cells shows that globin synthesis is not controlled by the hemin-controlled repressor of protein synthesis (HCR) nor by any specific translational control of globin synthesis by hemlin.     

Alterations in the transferrin receptor of human erythroleukemic cells after induction of hemoglobin synthesis

When K562 human erythroleukemic cells are induced to differentiate by addition of hemin to their medium, the number of binding sites for transferrin on the cell surface is substantially reduced. This reflects an internalization of receptors since no such reduction is observed when the total binding sites in soluble extracts of uninduced and differentiating cells are compared. The internalization of transferrin receptors has also been shown using lactoperoxidase-mediated radioiodination of cell surfaces and by immune precipitation of total and surface labeled receptors using an anti-receptor monoclonal antibody. Transferrin receptors from uninduced and differentiating cells were partially purified by affinity chromatography on transferrin-Sepharose and shown to be disulfide-bridged homodimers of a polypeptide with an apparent molecular weight of approximately 90,000. This protein is a phosphoprotein that can be resolved by isoelectric focusing into three major and two minor forms. By digestion with bacterial alkaline phosphatase, it was shown that at least four of these forms are probably phosphorylation variants of a single polypeptide. As differentiation proceeds, the proportions of the individual forms of the receptor change with a shift to the more phosphorylated polypeptides.     

Inhibition of transferrin receptor expression by interferon-alpha in human lymphoblastoid cells and mitogen-induced lymphocytes

125I-Transferrin binding to lymphoblastoid K562 and Daudi cells markedly increased after exposure of the cells to culture conditions that stimulated proliferation. Treatment of these cells with interferon-alpha (IFN-alpha) resulted in concurrent inhibition of cell growth and of the rise in transferrin binding. Scatchard analyses revealed that IFN reduced the number of transferrin receptors without altering the binding constant. When 125I-transferrin binding was measured using permeabilized cells, the IFN-induced reduction of binding was comparable to that observed with intact cells, indicating that IFN diminished the total number of cellular transferrin receptors. We also found that addition of IFN-alpha to phytohemagglutinin-stimulated human lymphocytes inhibited the mitogen-induced enhancement of [3H]thymidine incorporation as well as surface binding of 125I-transferrin. Our findings suggest that the decrease in transferrin receptor expression on IFN-alpha-treated cells may be one of the mechanisms responsible for the antiproliferative action of IFN.     

The role of transferrin in heme transport.

Porphyrin accumulation by proliferating cells, e.g., those associated with cancers or wounds, tends to correlate with increased transferrin receptor density. To determine whether transferrin might be implicated in porphyrin transport, fluorescence and absorption spectroscopy were used to study the interaction of porphyrins with transferrin. A single high-affinity binding site for heme and other porphyrins (Kd approximately 20-25 nM) was detected by fluorescence spectroscopy. Difference spectroscopy revealed three additional heme-binding sites. These sites were distinct from the iron-binding sites: 1) Apotransferrin and diferric transferrin bound porphyrins with equal affinity; 2) 59Fe was not displaced from transferrin by porphyrins. Murine erythroleukemia cells incubated with [59Fe]hemin-[125I]transferrin internalized both labels concomitantly. Accumulation of [59Fe]hemin could be blocked by a 100-fold excess of diferric transferrin but not by apotransferrin. These results indicate that cells can internalize exogenous heme, and possibly porphyrins, bound to transferrin via its receptor.     

5-Aminolevulinic acid stimulation of porphyrin and hemoglobin synthesis by uninduced Friend erythroleukemic cells.

Porphyrin synthesis and iron accumulation was stimulated by exogenous 5-aminolevulinic acid (ALA) in uninduced Friend erythroleukemic cells (FELC). Uroporphyrin and protoporphyrin were the major intermediated precursors produced. All porphyrin types were conjugated to protein insoluble cellular components and could be extracted only by methanol sulfuric acid esterification. Heme content of the uninduced FELC was increased 6-fold in the presence of 5 x 10(-4) M ALA. As a consequence, the synthesis of the minor murine hemoglobin component was preferentially induced, an effect similar to that expressed by exogenous hemin. Addition of exogenous ALA to 0.5% DMSO-induced cells increased total hemoglobin synthesis with a higher efficiency of the minor hemoglobin. The endogenous synthesis of porphyrin from exogenous ALA was markedly reduced by hemin. Uroporphyrin, coproporphyrin, protoporphyrin and heme were equally repressed, indicating an inhibitory effect of hemin on ALA dehydrase and urosynthetase activities. In addition, hemin repressed [3H]leucine incorporation into protein by uninduced cells. Incubation of uninduced cells in culture medium without serum in the presence of hemin blocked their protein synthesis activity, whereas addition of serum exerted a protective effect on living FELC.     

Synthesis and intracellular distribution of cathepsins E and D in differentiating murine Friend erythroleukemia cells.

The synthesis, accumulation, and cellular distribution of cathepsins E and D during the dimethyl sulfoxide (DMSO)-induced differentiation of Friend erythroleukemia cells were investigated. The cellular levels of cathepsins E and D rapidly increased within 1 day of DMSO induction and then sharply decreased over the next 7 days. Since the cells during 1 day of differentiation were morphologically the same as uninduced cells, the results suggest the importance of these enzymes in more cellular proteolysis for the following committed differentiation. While cathepsin D was present mostly in the sedimentable fraction of cells throughout the differentiation period, the distribution of cathepsin E varied to the stage of differentiation. The ratio of the soluble/sedimentable cathepsin E content was 1.1, 1.4, 0.9, and 0.7 in cells after 0, 1, 4, and 7 days of DMSO treatment, respectively. The maturation of reticulocytes to erythrocytes was accompanied by complete loss of the soluble cathepsin E and of all of the cellular cathepsin D. Immunoblotting analyses revealed that both uninduced and induced cells contained two forms of cathepsin E; a high molecular weight form (82 kDa) which was mainly associated with the sedimentable fraction and a low molecular weight form (74 kDa) which was found largely in the soluble fraction. The distribution of these two forms was not significantly changed throughout the differentiation period, but the 74-kDa protein was completely eliminated with maturation of reticulocytes to erythrocytes. Cathepsin D also appeared in two forms in both uninduced and induced cells; a minor (46 kDa) and a major (42 kDa) form which appear to have a precursor-product relationship.     

Effects of metalloporphyrins on hemoglobin formation in mouse Friend virus-transformed erythroleukemia cells. Stimulation of heme biosynthesis by cobalt protoporphyrin

Mouse Friend virus-transformed erythroleukemia cells in culture undergo erythroid differentiation when treated with a variety of compounds including iron protoporphyrin IX, i.e. hemin. Exogenous hemin is not only incorporated into hemoglobin in these cells but also stimulates heme biosynthesis (Granick, J. L., and Sassa, S. (1978) J. Biol. Chem. 253, 5402-5406). In this study, we examined whether metalloporphyrins other than hemin can also induce differentiation, and if so, whether they can also be incorporated into hemoglobin. Among eight metalloporphyrins examined in culture of these cells, i.e. Co, Mn, Cu, Mg, Ni, Zn, Sn, and Cd protoporphyrin IX, only Co protoporphyrin (10(-4) M) was found to significantly increase the biosynthesis of heme and hemoglobin. In contrast to hemin-mediated induction of erythroid differentiation, Co protoporphyrin was not incorporated into hemoglobin in Friend cells. These data indicate that Co protoporphyrin induces the formation of heme and hemoglobin in Friend cells and that these increases are due to the enhancement of heme biosynthetic activity.     

Virus production and hemoglobin synthesis in variant lines of dimethyl sulfoxide-treated Friend erythroleukemia cells.

Variant Friend erythroleukemia cell clones were compared in regard to their response to dimethyl sulfoxide and in their abilities to synthesize virus and hemoglobin. Clear evidence was obtained that cellular growth is required for virus production. The effects of dimethyl sulfoxide on virus production were not observed in cell lines that were resistant to growth perturbation by the compound. Studies of cell variants that were defective in either hemoglobin or virus synthesis indicate that these activities are independently regulated.     

Purine and phosphoribosylpyrophosphate synthesis in differentiating murine virus-induced erythroleukemic cells in vitro.

Phosphoribosylpyrophosphate synthetase activity was determined in Friend virus-inducted erythroleukemic cells in culture, stimulated to differentiate in the presence of dimethylsulfoxide. The activity of phosphoribosylpyrophosphate synthetase did not decrease in cells which had acquired the specialized function of hemoglobin synthesis, nor was the phosphoribosylpyrophosphate content of untreated erythroleukemic cells significantly different from that of cultures exposed to dimethylsulfoxide for 96 hours. However, the rate of the early steps of de novo purine biosynthesis as measured by the incorporation of [1-14C] glycine and [1-14C] formate into formyglycinamide ribonucleotide, was significantly lower in differentiating cell cultures. The addition of glutamine or ammonia increased glycine incorporation of control cultures, but failed to do so in treated cultures. In the course of the normal development of erythrocytes in vivo, phosphoribosylpyrophosphate synthetase activity is preserved, while the capacity to synthesize purines de novo is lost, as is the activity of the phosphoribosyl-l-amine synthesizing enzymes. Our present study suggests that the rate of de novo purine biosynthesis in this erythroleukemic cell line is not limited by the availability of phosphoribosylphrophosphate, but rather by a decrease in the phosphoribosyl-l-amine synthesizing enzymes. These findings provide further evidence that during dimethylsulfoxide-stimulated erythroid maturation, the same regulatory mechanisms are operative as in normal cellular development, and that ammonia-dependent purine biosynthesis is subject to the same regulatory mechanisms as is glutamine-dependent biosynthesis.     

Nucleosome-associated proteins and phosphoproteins of differentiating Friend erythroleukemia cells.

Mononucleosomes derived from brief digestion of uninduced Friend cell nuclei with micrococcal nuclease contain a set of non-histone chromosomal proteins which are partly or altogether missing in the oligomeric nucleosomes. On the other hand, the latter contain a protein of Mr 190,000 not seen in the mononucleosomes. Longer digestion removes most of these non-histone proteins, excepting the Mr 190,000 protein. Brief digestion of nuclei from Friend cells induced by DMSO or by n-butyrate removes most of the non-histone proteins from the nucleosomes, as did the prolonged digestion of uninduced nuclei. The Mr 190,000 protein remains, while a protein of Mr 27,000 is increased. The rate of phosphorylation of histone H1 associated with mononucleosomes was 3 to 4-fold greater in cells induced with DMSO. The major phosphoprotein and most of the other phosphorylated non-histones were modified at the same rate in control and induced cells. However, a Mr 95,000 protein was less phosphorylated in the induced cells.     

Effects of interferon on hemoglobin synthesis and leukemia virus production in Friend cells

Establishment of the antiviral state by interferon does not impair differentiation of Friend cells. Interferon actually produces an increase in dimethylsulfoxide-induced hemoglobin synthesis. However, both the constitutive production and the induction of leukemia virus in these cells are inhibited by interferon.